DE599207C - Switch with arc extinguishing by compressed gas - Google Patents

Description

GERMAN EMPIRE

ψ Vt, -

ISSUED ON
JUNE 27, 1934

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21c GROUP 35 ίο

S) ipi.-3ng. Sigwart Ruppel in Frankfurt a. M. Switch with arc extinguishing by compressed gas

Patented in the German Empire on May 24, 1929

There are known switches with arc extinguishing by compressed gas, the contacts in a sleeve through which compressed gas flows, at one end of which the fixed contact is arranged. In the case of such switches, brief blowing is sufficient to extinguish the arc. gen. As experience has shown, the arc is already over after a current change,

ie with 5-period alternating current after ¹ Z ₁₀₀ seconds counted from the moment of contact separation, extinguished. After this point in time, however, the contact distance must be increased even further up to the separation distance in order to prevent the arc from re-igniting after the flow of compressed gas has been switched off.

The known arrangement in which the moving pin-shaped contact is permanently within remains of the envelope through which compressed gas flows, now has certain disadvantages, because after the arc has been extinguished for the first time, which takes place at the moment of the zero crossing of the AC curve, the top of the Pin contact still afterglow and ions in their environment and especially in the Sends switching path. As a result, the pressurized gas flow, the flows over the pin contact into the opening of the mating contact in which Way that it first transports the ions from the pin electrode to the hollow electrode and thereby favoring the ionization of the switching path instead of eliminating it. Only in the further course of the switching process, when the ion emission at the pin electrode as a result of increasing cooling stops, the switching path is also cleaned. So it becomes to re-ignite the interrupting arc to prevent through this ionized switching path through, a relatively long switching travel and a correspondingly high switching speed are required.

Here the invention brings a substantial advance, through such a step Arrangement of the moving contact, so that when the power is switched off after the current has been interrupted, it is removed from the stationary Contact the opposite end of the sheath emerges and visibly enters the outside of the same in the open air final switch-off position moved on. This is because the ion-emitting The tip of the pin contact is brought out of the area of that flow of compressed gas, which flows towards the hollow electrode, so that no ions and conductive so-called residual gases from the pin electrode into the Switching path are blown and therefore the prevention of reignition of the Interruption arc required cleaning of the switching path from conductive components is brought about much faster. This effect is still favored in that the pressurized gas stream splits and, during the main part, as usual, through the hollow contact flows off, even a smaller one

Part of the pin contact through the opening through which it is pulled out of the switching chamber is, follows, so that a particularly effective insulating barrier between the two electrodes takes place. By this effect of the arrangement according to the invention it is achieved that one gets by with shorter switching paths and as a result, the switch can be made smaller and shorter ίο. A reduction in the shift travel also means a simplification of the drive device and the entire linkage. The reduction in size of the switching chamber is therefore not achieved solely by covering part of the switching path outside the switching chamber in the open air will, but in addition, a further shortening of the switching chamber achieved in that the entire switching path itself, as explained above, becomes smaller. This downsizing of the switching chamber In addition to the structural reduction in price, it also grants the advantage that should not be underestimated a significant gas saving, because not before the start of the extinguishing process large space needs to be filled with gas as with known switches, but rather only a small switching chamber that can be kept so short that the switching path of the moving contact inside only a switching time of a little more than Vioo sec. is equivalent to. This simplification of the structure enables the switch structure to be met similarly to disconnectors; the only difference is that the fixed contact is replaced by the pressurized gas-blown sleeve with nozzle contact will. Furthermore, the operational reliability is significantly increased that the moving Contacts in the switch-off position are visible. This is because the possibility arises a check that all phases have actually been interrupted, and ■ the operating staff is not only concerned with reliability instructed by contact position indicators, the vein in the event of crossbeam breakage similar faults can fail. The visible separation point can be used as a Use circuit breakers and, for example, save a set of circuit breakers if you simply with the holder open between the contact pin and the outlet opening of the Switching chamber an insulating plate or the like. Slides in to prevent accidental switch-on to prevent.

Although an oil switch is known in which the moving contacts from the switch pots can be pulled out into the open, so that the movable contacts are also visible when the device is switched off. in the The rest of the time, the advantages achieved by the invention in terms of extinguishing technology and structural type, since the extinguishing conditions in such oil switches with those are not comparable with gas switches.

So that when the gas pressure switch is switched off, the insulating Pressurized gas layer is retained between the contacts, the arrangement is appropriate taken so that even after the moving contact has left the switching chamber, the flow of pressurized gas still briefly continues to blow, in the same direction as during the arc extinction, so that the ionized gases with certainty to the opening of the nozzle-shaped contact be blown and not be able to follow the moving contact. One can also have a simple structure of the switch achieve that normalized switch parts (switching chambers, nozzles, supply pipes and the like.) Are produced and that Switches for different voltages are formed in a simple manner in that the corresponding parts to match the respective voltage (normal supporters, etc.) for Construction can be used.

Exemplary embodiments of the invention are shown in the drawing.

Fig. Ι shows a switching chamber 3, 4, in which the nozzle 3, the one contact forms, made of metal and the sheath 4 made of insulating material. One could also chamber and Make the nozzle out of insulating material and use the nozzle contact 3 in particular or also make the contact 3 and the sleeve 4 entirely from metal and only with the inside Line insulating material and provide with an insulating floor. In all cases it is on the Take into account the heat effects of the arc. Instead of using a special nozzle 3, you can also use the suction or suction device to be attached above the switch. Unite the discharge pipe of the switch gases and place it on the gap chamber 4.

As can be seen from the section (side view) in Fig. 2, the shell 4 of two or three insulating tubes 9 carried, all or optionally individually the Form pressurized gas feed to the shell 4. If only one pipe is used, the others can Parts 9 can also be full body. These tubes 9 contribute at the same time. 7 the power supply tion 2 (sleeve contact) to the moving contact 1, which is driven in any way is. The drive is shown by an insulating connecting rod 10, which is driven by a ΖγΗπ * - the 16 is moved from. When arranging several poles next to each other (see Fig. 1) the poles are driven by a

common shaft 12. The drive and the pressurized gas vessel 15 can be in the switch frame 18 be arranged, in which by the support 17 and the support piece 7 of the upper Part of the switch stiffened and the power supply 2 is carried. The compressed gas is controlled by the valve 14 and when using multiple tubes by one Distributor 13 distributed to the various tubes and different poles.

In Fig. 3 an arrangement is shown in which the switching chamber 4 directly on upper part of a compressed gas supply pipe 9 is attached and in which the movable Pole 1 is moved obliquely out of the tube 9. Here, too, the switching chamber be designed in different ways. It can also be placed on the tube 9 as a special part. the

ao power supply 2 is attached to a post insulator 20 on which the connection and Support piece 7 is also attached isolated. The support frame 18 carries the drive device, parts 10, 11 and 12 of the drive, the cylinder 16 and the compressed gas vessel 15, so that in a three-phase arrangement the three Poles can be driven together and can sit in one plane. The pressurized gas mechanism with accessories can sit below the floor, which ends at level 13, like this that only the actual switch sits above the floor. Here, as with the other arrangements, you can encapsulate the whole arrangement. The frame 18 would be the result in a closed rear wall - and the front wall would have to be at a corresponding distance from the power supply 2 are attached. It must be so far away that the insulating piece 10 can move freely.

All parts are accessible after removing the front wall.

Fig. 4 shows an arrangement in which a free-seated switching chamber 4, 3 is supported by a post insulator.

The insulating blowpipe 22 fed in at an angle from below contributes to the stiffening. The insulator 21 carries the sliding contact 2, which is covered by a removable cover 8 is. "An insulating stiffener 23 supports the contact 2, which is well guided and absorbs any stresses against the frame 18 from. The drive is carried out in a similar way to the ones previously described Executions; however, any other type of drive can also be selected.

In the embodiment according to Fig. 5

the switch is horizontal. An inclined insulating tube 22 supplies the compressed gas. Of the Drive cylinder 16, the pressurized gas vessel 15 and the valve 14 with the manifold 13 are drawn below the floor. Even such an arrangement can be encapsulated. Instead of the inclined tube 22 you can also Use a hollow support attached under the switching chamber 4 to supply compressed gas.

In Figs. 6, 7 and 8 an arrangement is drawn in which the structure is similar In the same way as with a rotary disconnector. The moving piece 1 represents that Current connector and connects the two poles with each other, which are on the hollow, at the same time serving for the compressed gas supply insulating bodies 19 rest. The switching chambers 4, 3 must be shaped according to the rotary movement. Instead of supplying the compressed gas through the hollow support 19, can it can also be fed through special pipes that direct the jet of pressurized gas in the direction of the Blow the ends of the contact piece 1. Then the Schaltitammer is correspondingly different to shape. The rotation of the contact piece 1 takes place via a support 26 through the. common drive 28, which in the case of several adjacent poles also the other Poles moved along .. Should be prevented that from the openings of the switching chamber Pressurized gas emerges, so you can through flaps or the like. The switching chamber after removal of the contact piece 1 complete. You can also use the openings through which the contact 1 passes through easily seals, e.g. B. Felt seals, attach.

Claims (7)

Patent claims: i. Switch with arc quenching by compressed gas, its contacts in a Sheath through which compressed gas flows are separated, at one end of which the fixed contact is arranged, through which the compressed gas emerges from the envelope, characterized by an arrangement of the moving contact such that he during the shutdown process after a power interruption from the fixed Contact opposite end of the sheath leaks and is visible outside of the same in the open air Way into the final switch-off position 1 ». 2. Switch according to claim 1, characterized in that the switching speed is selected such that the moving contact does not leave the shell before ¹ Z ₁₀₀ seconds after the contact has been separated. 3. Switch according to claim 1, characterized in that the compressed gas blowing the separation point after the moving contact has left the cover, persists for a short time. 4 · switch according to claim ι to 3, at which the fixed contact is designed as a nozzle for the exiting stream of pressurized gas is, characterized in that the axis of the nozzle is inclined relative to the axis of the shell and that the shell is a has lateral opening lying in the direction of the nozzle axis through which the Pin contact is pulled out of the tube (Fig. 3). 5. Switch according to claim 1 to 4, characterized in that the supporter (21) for the arcing chamber (4), the support (20) for the power supply (2), the earthed switch drive shaft (12) and the compressed gas supply (13) with the distributor valve (14) are arranged one below the other on a common frame. 6. Switch according to claim 1 to 5, the contact movement in the horizontal Direction takes place, characterized in that for guiding the moving contact (1) in addition to the power supply (2) a special one, also from earth insulated guide device (8) is provided (Fig. 5); 7. Switch according to claim 1 with double break, characterized in that a rotatable insulator (26) is known per se in rotary disconnectors Way an S-shaped, moving contact piece common to both interruption points (1) and that the isolators (19) carrying the switching chambers (4) at the same time serve as supply pipes for the compressed gas (Fig. 6 to 8). 1 sheet of drawings